Investigating and improving student understanding of the basics of quantum computing

TL;DR

This paper presents the development and validation of an interactive tutorial designed to improve student understanding of quantum computing fundamentals, demonstrating significant learning gains through implementation in physics courses.

Contribution

It introduces a validated, inquiry-based Quantum Interactive Learning Tutorial (QuILT) that enhances student comprehension of quantum computing concepts beyond traditional instruction.

Findings

Students showed improved understanding after using the tutorial.

The tutorial effectively addresses common student difficulties.

Implementation in different courses confirmed its broad applicability.

Abstract

Quantum information science and engineering (QISE) is a rapidly developing field that leverages the skills of experts from many disciplines to utilize the potential of quantum systems in a variety of applications. It requires talent from a wide variety of traditional fields, including physics, engineering, chemistry, and computer science, to name a few. To prepare students for such opportunities, it is important to give them a strong foundation in the basics of QISE, in which quantum computing plays a central role. In this study, we discuss the development, validation, and evaluation of a QuILT, or Quantum Interactive Learning Tutorial, on the basics and applications of quantum computing. These include an overview of key quantum mechanical concepts relevant for quantum computation (including ways a quantum computer is different from a classical computer), properties of single- and multi-qubit systems, and the basics of single-qubit quantum gates. The tutorial uses guided inquiry-based teaching-learning sequences. Its development and validation involved conducting cognitive task analysis from both expert and student perspectives and using common student difficulties as a guide. The inquiry-based learning sequences in the tutorial provide scaffolding support to help students develop a functional understanding. The final version of the validated tutorial was implemented in two distinct courses offered by the physics department with slightly different student populations and broader course goals. Students' understanding was evaluated after traditional lecture-based instruction on the requisite concepts, and again after engaging with the tutorial. We analyze and discuss their improvement in performance on concepts covered in the tutorial.